Level shifter circuit of driving device

ABSTRACT

A level shifter circuit of a driving device includes first and second pulse generators, first and second level shifters, and a determination circuit. The first pulse generator provides a first input signal according to a high-voltage signal. The first input signal includes a pulse signal having a first current level and a sustain signal having a second current level following the pulse signal. The first level shifter receives the first input signal to generate a first indication signal. The second pulse generator provides a second input signal according to the high-voltage signal. The second input signal includes the pulse signal and the sustain signal following the pulse signal. The second level shifter receives the second input signal to generate a second indication signal. The determination circuit generates a low-voltage signal according to the first indication signal and the second indication signal.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the priority benefit of Chinese application no.202210133700.2, filed on Feb. 14, 2022. The entirety of theabove-mentioned patent application is hereby incorporated by referenceherein and made a part of this specification.

BACKGROUND Technical Field

The disclosure relates to a level shifter circuit. In particular, thedisclosure relates to a level shifter circuit of a driving device of apower switch in a power conversion device.

Description of Related Art

With reference to FIG. 1 , FIG. 1 is a schematic block diagram of aconventional driving device. A logic unit 110 generates a logic outputsignal OUT to a driving signal level shifter circuit 121 according topulse width modulation signals PWM_H and PWM_L. The driving signal levelshifter circuit 121 may convert the logic output signal OUT from a lowvoltage domain into a high voltage domain, for a first driver 131 toaccordingly generate a driving signal UG in a high voltage domain todrive a high-side power switch (not shown). A second driver 132 maygenerate a driving signal LG in a low voltage domain according to theoutput signal of the logic unit 110 to drive a low-side power switch(not shown). A level shifter circuit 122 may obtain a high-voltagesignal HV_IN according to an output of the first driver 131, convert thehigh-voltage signal HV_IN into a low-voltage signal LV_OUT, and providethe low-voltage signal LV_OUT to the logic unit 110.

With reference to FIG. 2 , FIG. 2 is a schematic conventional circuitdiagram of the level shifter circuit 122 in FIG. 1 . A high-voltagetransistor 201 receives the high-voltage signal HV_IN, and outputs thelow-voltage signal LV_OUT. In the application of a power conversiondevice system, a high-voltage ground signal HV_GND is the output nodevoltage of the power conversion device, and may switch between theworking voltage and the ground voltage. When the high-voltage groundsignal HV_GND rises, parasitic capacitance 202 between a controlterminal and a second terminal of the high-voltage transistor 201 maytransmit currents I_C to a circuit node N1, and the voltage level of thelow-voltage output signal LV_OUT may be pulled up synchronously. In theapplication of high-speed switching, this phenomenon may causeserroneous determination by the logic unit 110.

SUMMARY

The disclosure is directed to a level shifter circuit of a drivingdevice, which effectively prevents erroneous output determination causedby changes in a high-voltage ground signal and a high-voltage power.

According to an embodiment of the disclosure, a level shifter circuit ofa driving device is configured to convert a high-voltage signal into alow-voltage signal. The level shifter circuit includes a first pulsegenerator, a first level shifter, a second pulse generator, a secondlevel shifter, and a determination circuit. The first pulse generatorprovides a first input signal according to the high-voltage signal. Thefirst input signal includes a pulse signal having a first current leveland a sustain signal following the pulse signal and having a secondcurrent level. The first current level is higher than the second currentlevel. The first level shifter is coupled to the first pulse generator.The first level shifter receives the first input signal to generate afirst indication signal. The second pulse generator provides a secondinput signal according to the high-voltage signal. The second inputsignal includes the pulse signal and the sustain signal following thepulse signal. The second level shifter is coupled to the second pulsegenerator. The second level shifter receives the second input signal togenerate a second indication signal. The determination circuit iscoupled to the first level shifter and the second level shifter. Thedetermination circuit generates the low-voltage signal according to thefirst indication signal and the second indication signal.

In an embodiment, the pulse signal and the sustain signal of the firstinput signal occur during a period corresponding to when thehigh-voltage signal is at a high voltage level.

In an embodiment, the pulse signal and the sustain signal of the secondinput signal occur during a period corresponding to when thehigh-voltage signal is at a low voltage level.

In an embodiment, the first current level is ten times or more higherthan the second current level.

In an embodiment, a duration of the pulse signal of the first inputsignal and the second input signal is 10% to 20% of a time length of aduty cycle of the high-voltage signal.

In an embodiment, the sustain signal of the first input signal is cutoff according to a falling edge of the high-voltage signal, and thesustain signal of the second input signal is cut off according to arising edge of the high-voltage signal.

In an embodiment, the determination circuit includes a latch circuit anda determination logic. The latch circuit is coupled to the first levelshifter and the second level shifter. The latch circuit generates afirst square-wave signal and a second square-wave signal according tothe first indication signal and the second indication signal. Thedetermination logic is coupled to the latch circuit. The determinationlogic generates the low-voltage output signal according to the firstsquare-wave signal and the second square-wave signal.

In an embodiment, the level shifter circuit further includes a diode. Afirst terminal of the diode is coupled to the latch circuit. A secondterminal of the diode is coupled to the second level shifter.

In an embodiment, the determination logic includes a logic gate and alatch control circuit. The logic gate receives the first square-wavesignal and the second square-wave signal, and accordingly generates ablock signal. The latch control circuit generates the low-voltage signalaccording to the first square-wave signal, the second square-wavesignal, and the block signal.

In an embodiment, the determination logic further includes a first delaycircuit and a second delay circuit. The first delay circuit and thesecond delay circuit respectively receive the first square-wave signaland the second square-wave signal and generate a delayed firstsquare-wave signal and a delayed second square-wave signal. Thedetermination logic generates the low-voltage signal according to thedelayed first square-wave signal and the delayed second square-wavesignal.

In an embodiment of the disclosure, the driving device receives a pulsewidth modulation signal and generates a driving signal. The drivingdevice further includes a logic unit, a driving signal level shiftercircuit, a first driver, and the level shifter circuit. The logic unitreceives the pulse width modulation signal and generates a logic outputsignal. The driving signal level shifter circuit is coupled to the logicunit. The driving signal level shifter circuit receives the logic outputsignal and converts the logic output signal from a low voltage domaininto a high voltage domain. The first driver is coupled to the drivingsignal level shifter circuit. The first driver generates the drivingsignal according to the logic output signal in the high voltage domain.The level shifter circuit is coupled between the first driver and thelogic unit. The level shifter circuit obtains the high-voltage signalaccording to the driving signal and converts the high-voltage signalinto the low-voltage signal.

Based on the foregoing, according to the embodiments of the disclosure,the level shifter circuit of the driving device may generate inputsignals including a pulse signal and a sustain signal having a lowcurrent level according to the high-voltage signal, and generatecorresponding indication signals according to the input signals for thedetermination circuit to accordingly generate a correct and stablelow-voltage signal, without being affected by changes in thehigh-voltage ground signal and/or the high-voltage power.

To make the aforementioned more comprehensible, several embodimentsaccompanied with drawings are described in detail as follows.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings are included to provide a furtherunderstanding of the disclosure, and are incorporated in and constitutea part of this specification. The drawings illustrate exemplaryembodiments of the disclosure and, together with the description, serveto explain the principles of the disclosure.

FIG. 1 is a schematic block diagram of a conventional driving device.

FIG. 2 is a schematic conventional circuit diagram of the level shiftercircuit in FIG. 1 .

FIG. 3 is a schematic block diagram of a level shifter circuit of anembodiment of the disclosure.

FIG. 4 is a schematic circuit diagram of a level shifter circuit of anembodiment of the disclosure.

FIG. 5 is a signal signal diagram of voltage signals and current signalsof an embodiment of the disclosure.

DESCRIPTION OF THE EMBODIMENTS

Reference will now be made in detail to the exemplary embodiments of thedisclosure, examples of which are illustrated in the accompanyingdrawings. Wherever possible, the same reference numerals are used in thedrawings and descriptions to refer to the same or like parts.

FIG. 3 is a schematic block diagram of a level shifter circuit of anembodiment of the disclosure. With reference to FIG. 1 and FIG. 3 , inan embodiment of the disclosure, a driving device includes the logicunit 110, the first driver 131, and the level shifter circuit 122 ofFIG. 1 , and includes a level shifter circuit 300 of FIG. 3 . It shouldbe noted that, in the driving device of the embodiment of thedisclosure, the specific internal circuits of the level shifter circuit122 in FIG. 1 is realized by the level shifter circuit 300 in FIG. 3 .With reference to FIG. 1 , the logic unit 110 receives the pulse widthmodulation signal PWM_H/PWM_L and generates the logic output signal OUT.The driving signal level shifter circuit 121 is coupled to the logicunit 110, receives the logic output signal OUT, and converts the logicoutput signal OUT from a low voltage domain into a high voltage domain.The first driver 131 is coupled to the driving signal level shiftercircuit 121 and generates the driving signal UG according to the outputsignal HV_OUT in a high voltage domain. The level shifter circuit 122 iscoupled between the first driver 131 and the logic unit 110, obtains thehigh-voltage signal HV_IN according to the driving signal UG, andconverts the high-voltage signal HV_IN into the low-voltage signalLV_OUT.

With reference to FIG. 3 , the level shifter circuit 300 is adapted to adriving device. The level shifter circuit 300 includes an inverter 301,a first pulse generator 302, a second pulse generator 303, a first levelshifter 304, a second level shifter 305, and a determination circuit306. An input terminal of the inverter 301 receives the high-voltagesignal HV_IN, and an output terminal of the inverter 301 may output aninverted high-voltage signal HV_INB. The output terminal of the inverter301 is coupled to the first pulse generator 302. The second pulsegenerator 303 receives the high-voltage signal HV_IN. In thisembodiment, the first pulse generator 302 may provide a first inputsignal PC1 according to rising edge triggering of the high-voltagesignal HV_IN. The first level shifter 304 is coupled to the first pulsegenerator 302, and may receive the first input signal PC1 to generate afirst indication signal LV_IN. The second pulse generator 303 mayprovide a second input signal PC2 according to falling edge triggeringof the high-voltage signal HV_IN. The second level shifter 305 iscoupled to the second pulse generator 303, and may receive the secondinput signal PC2 to generate a second indication signal LV_INB. Thedetermination circuit 306 is coupled to the first level shifter 304 andthe second level shifter 305, and may generate the low-voltage signalLV_OUT according to the first indication signal LV_IN and the secondindication signal LV_INB.

In this embodiment, the determination circuit 306 includes a latchcircuit 3061 and a determination logic 3062. A set terminal (S) of thelatch circuit 3061 is coupled to the first level shifter 304, and areset terminal (R) of the latch circuit 3061 is coupled to the secondlevel shifter 305. The latch circuit 3061 may output a first square-wavesignal LV_SNS0 and a second square-wave signal LV_SNS0B from an outputterminal (Q) and a complementary output terminal (QB) according to thefirst indication signal LV_IN and the second indication signal LV_INB.The determination logic 3062 is coupled to the output terminal (Q) andthe complementary output terminal (QB) of the latch circuit 3061. Thedetermination logic 3062 may generate the low-voltage signal LV_OUTaccording to the first square-wave signal LV_SNS0 and the secondsquare-wave signal LV_SNS0B.

FIG. 4 is a schematic circuit diagram of a level shifter circuit of anembodiment of the disclosure. With reference to FIG. 4 , a level shiftercircuit 400 in FIG. 4 may be a specific example of circuitimplementation for the level shifter circuit 300 in FIG. 3 above. Inthis embodiment, an input terminal of a first inverter 401 is coupled toa high-voltage input terminal 414 to receive the high-voltage signalHV_IN. An output terminal of the first inverter 401 is coupled to afirst pulse generator 403 to provide the inverted high-voltage signalHV_INB to the first pulse generator 403. An input terminal of a secondinverter 402 is coupled to the output terminal of the first inverter 401to receive the inverted high-voltage signal HV_INB. An output terminalof the second inverter 402 is coupled to a second pulse generator 404 toprovide the high-voltage signal HV_IN to the second pulse generator 404.

In this embodiment, the first pulse generator 403 is coupled to a firstlevel shifter 405. The first pulse generator 403 provides the firstinput signal PC1 to the first level shifter 405 according to rising edgetriggering of the high-voltage signal HV_IN. The second pulse generator404 is coupled to a second level shifter 406. The second pulse generator404 provides the second input signal PC2 to the second level shifter 406according to falling edge triggering of the high-voltage signal HV_IN.In this embodiment, the first level shifter 405 includes a high-voltageP-type transistor 4051. For example, the high-voltage P-type transistor4051 may be a high-voltage P-type metal-oxide-semiconductor field-effecttransistor (MOSFET). A first terminal of the high-voltage P-typetransistor 4051 is coupled to the first pulse generator 403. A controlterminal of the high-voltage P-type transistor 4051 is coupled to ahigh-voltage ground terminal 415. A second terminal of the high-voltageP-type transistor 4051 is coupled to a latch circuit 407. The secondlevel shifter 406 includes a high-voltage P-type transistor 4061. Forexample, the high-voltage P-type transistor 4061 may be a high-voltageP-type MOSFET. A first terminal of the high-voltage P-type transistor4061 is coupled to the second pulse generator 404. A control terminal ofthe high-voltage P-type transistor 4061 is coupled to a high-voltageground terminal 416. A second terminal of the high-voltage P-typetransistor 4061 is coupled to a transistor 409, a diode 410, and asecond voltage clamping circuit 411. The diode 410 is a body diode ofthe transistor 409, for preventing reverse current flows when thehigh-voltage ground terminal HV_GND is at an excessively low voltage. Inparticular, in applications of a gallium nitride (GaN) transistor as apower switch, the voltage of the high-voltage ground terminal HV_GND isparticularly likely to drop to a negative voltage and cause currentreverse current flows. The transistor 409 may be a P-type transistor. Ananode of the diode 410 is coupled to the latch circuit 407. A cathode ofthe diode 410 is coupled to a second terminal of the transistor 409, thesecond terminal of the high-voltage P-type transistor 4061, and thesecond voltage clamping circuit 411. In other words, a first terminal ofthe diode 410 is coupled to the latch circuit 3061, and a secondterminal of the diode 410 is coupled to the second level shifter 305.

The latch circuit 407 includes transistors 4071 to 4074. The transistor4071 may be a P-type transistor, and the transistors 4072 to 4074 may beN-type transistors. A first terminal of the transistor 4071 is coupledto a power supply voltage LV_PWR. A control terminal of the transistor4071 is coupled to the second terminal of the high-voltage P-typetransistor 4051 of the first level shifter 405 and receives the firstindication signal LV_IN output by the second terminal of thehigh-voltage P-type transistor 4051. A second terminal of the transistor4071 is coupled to the second level shifter 406 through the diode 410and receives the second indication signal LV_INB output by the secondterminal of the high-voltage P-type transistor 4061. A first terminal ofthe transistor 4072 is coupled to the second terminal of the transistor4071 and receives the second indication signal LV_INB output by thesecond terminal of the high-voltage P-type transistor 4061. A controlterminal of the transistor 4072 is coupled to the control terminal ofthe transistor 4071 and receives the first indication signal LV_IN. Asecond terminal of the transistor 4072 is coupled to the ground voltage.A first terminal of the transistor 4073 is coupled to the controlterminal of the transistor 4071 and receives the first indication signalLV_IN. A control terminal of the transistor 4073 is coupled to thesecond terminal of the transistor 4071 and receives the secondindication signal LV_INB output by the second terminal of thehigh-voltage P-type transistor 4061. A first terminal of the transistor4074 is coupled to a second terminal of the transistor 4073. A secondterminal of the transistor 4074 is coupled to the ground voltage. Acontrol terminal of the transistor 4074 is coupled to a sensingprotection control circuit 412. The control terminal of the transistor4071 and the control terminal of the transistor 4072 are coupled to afirst voltage clamping circuit 408. It should be noted that, in anembodiment, the area of the transistor 4073 may be greater than the areaof the transistor 4072 to provide a greater pull-down current. In thecase that drive currents exist at the control terminals of bothtransistors, the transistor 4073 is turned on prior to the transistor4072 to function as a latch.

In this embodiment, the input signals PC1 and PC2 generated by the pulsegenerators 403 and 404 are current signals. The current signals includea pulse signal having a first current level (e.g., 3 milliamps (mA)) anda sustain signal following the pulse signal and having a second currentlevel (e.g., 100 microamperes (μA)). A control terminal of thetransistor in the latch circuit 407 is turned on when receiving thecurrent signal of the pulse signal. After that, the conduction state ofthe transistor is maintained by the current signal of the sustainsignal. When the current signal is zero current, the transistor is notturned on. In other words, the transistor in the latch circuit is turnedon in the presence of a current, and may output a voltage signal at alogic high level; the transistor in the latch circuit is not turned onin the absence of a current, and may output a voltage signal at a logiclow level, accordingly achieving the effect of a latch circuit with lowpower consumption.

A determination logic 413 includes a logic gate 4131, a first delaycircuit 4132, a second delay circuit 4133, and a latch control circuit4134. The logic gate 4131 may be an AND gate. A first input terminal ofthe logic gate 4131 and an input terminal of the first delay circuit4132 are coupled to the control terminal of the transistor 4071 of thelatch circuit 407, the control terminal of the transistor 4072, thefirst terminal of the transistor 4073, and an output terminal of thehigh-voltage P-type transistor 4051. The first input terminal of thelogic gate 4131 and the input terminal of the first delay circuit 4132may receive the first square-wave signal LV_SNS0 generated by the latchcircuit 407 according to the first indication signal LV_IN. A secondinput terminal of the logic gate 4131 and an input terminal of thesecond delay circuit 4133 are coupled to the second terminal of thetransistor 4071 of the latch circuit 407, the first terminal of thetransistor 4072, the control terminal of the transistor 4073, and anoutput terminal of the high-voltage P-type transistor 4061. The secondinput terminal of the logic gate 4131 and the input terminal of thesecond delay circuit 4133 may receive the second square-wave signalLV_SNS0B generated by the latch circuit 407 according to the secondindication signal LV_INB. The logic gate 4131 may generate a blocksignal SRBLK according to the first square-wave signal LV_SNS0 and thesecond square-wave signal LV_SNS0B, and provide the block signal SRBLKfrom an output terminal to the latch control circuit 4134. An outputterminal of the first delay circuit 4132 may output a delayed firstsquare-wave signal LV_SNS0 to the latch control circuit 4134. An outputterminal of the second delay circuit 4133 may output a delayed secondsquare-wave signal LV_SNS0B to the latch control circuit 4134. The latchcontrol circuit 4134 may generate the low-voltage signal LV_OUT to alow-voltage output terminal 417 according to the first square-wavesignal LV_SNS0, the second square-wave signal LV_SNS0B, and the blocksignal SRBLK. The low-voltage output terminal 417 may also be coupled toa rear-end logic circuit, which is not limited by the disclosure.

In addition, in an embodiment, the sensing protection control circuit412 may be configured to receive a control signal sent by an externalsystem under special circumstances, and turn off the transistor 4074 tolock the output of the latch circuit 407.

FIG. 5 is a signal signal diagram of voltage signals and current signalsof an embodiment of the disclosure. With reference to FIG. 4 and FIG. 5together, the signal changes of voltage signals and current signals inFIG. 5 are taken as an example in the description below. Before time t1,the high-voltage signal HV_IN is at a low voltage level (e.g., 5 volts(V)). The first pulse generator 403 continuously generates the firstinput signal PC1 having a zero current level (e.g., 0 A). The secondpulse generator 404 continuously generates the second input signal PC2including the sustain signal having a low current level (e.g., 100 μA).At this time, the transistors 4071, 4073, 4074 are turned on, and thetransistor 4072 is turned off. The second terminal of the high-voltageP-type transistor 4051 of the first level shifter 405 continuouslyoutputs the first indication signal LV_IN having a low voltage level(e.g., 0V). The second terminal of the high-voltage P-type transistor4061 of the second level shifter 406 continuously outputs the secondindication signal LV_INB having a high voltage level (e.g., 5V). Assuch, the latch circuit 407 outputs the first square-wave signal LV_SNS0corresponding to a logic low level (e.g., 0V) and the second square-wavesignal LV_SNS0B corresponding to a logic high level (e.g., 5V). Thelogic gate 4131 outputs the block signal SRBLK at a logic low level(e.g., 0V). Accordingly, the latch control circuit 4134 may output thelow-voltage signal LV_OUT having a low voltage level (e.g., 0V).

At time t1, the high-voltage signal HV_IN is at a high voltage level(e.g., 10V). The first pulse generator 403 provides the first inputsignal PC1 of a pulse signal having a high current level (e.g., 3 mA)according to rising edge triggering of the high-voltage signal HV_IN.The second pulse generator 404 provides the second input signal PC2having a zero current level (e.g., OA) (i.e., stops output a currentsignal) according to falling edge of the inverted high-voltage signalHV_INB. The second input signal PC2 is cut off according to the fallingedge of the inverted high-voltage signal HV_INB (i.e., cut off accordingto the rising edge of the high-voltage signal HV_IN). At this time, thetransistor 4071 is turned off, and the transistor 4072 is turned on. Thesecond terminal of the high-voltage P-type transistor 4051 of the firstlevel shifter 405 outputs the first indication signal LV_IN having ahigh voltage level (e.g., 5V). The second terminal output of thehigh-voltage P-type transistor 4061 of the second level shifter 406outputs the second indication signal LV_INB having a low voltage level(e.g., 0V). As such, the latch circuit 407 outputs the first square-wavesignal LV_SNS0 corresponding to a logic high level (e.g., 5V) and thesecond square-wave signal LV_SNS0B corresponding to a logic low level(e.g., 0V). The logic gate 4131 continuously outputs the block signalSRBLK at a logic low level (e.g., 0V). Accordingly, the latch controlcircuit 4134 may output the low-voltage signal LV_OUT having a highvoltage level (e.g., 5V) according to the first square-wave signalLV_SNS0 and the second square-wave signal LV_SNS0B delayed fornanoseconds (ns) by the first delay circuit 4132 and the second delaycircuit 4133 being leading edge-triggered.

At time t2, the first pulse generator 403 provides a sustain signalfollowing the pulse signal and having a low current level (e.g., 100 μA)of the first input signal PC1 to maintain the transistors 4071 to 4073of the latch circuit 407 to be turned on, so that the latch circuit 407maintains outputting the first square-wave signal LV_SNS0 correspondingto a logic high level (e.g., 5V). As such, the circuit power consumptioncan be effectively reduced, and the latch circuit 407 can also be keptin a locked state. In addition, under the premise of ensuring andmaintaining the transistor to be turned on, the high current level canbe ten times or more higher than the low current level.

At time t3, since the high-voltage signal HV_IN is converted into a lowvoltage level (e.g., 5V), the first pulse generator 403 generates thefirst input signal PC1 having a zero current level (e.g., 0 A). Thefirst input signal PC1 is cut off according to the falling edge of thehigh-voltage signal HV_IN. Moreover, the second pulse generator 404 mayprovide the second input signal PC2 of a pulse signal having a highcurrent level (e.g., 3 mA) according to rising edge triggering of theinverted high-voltage signal HV_INB (i.e., falling edge of thehigh-voltage signal HV_IN). At this time, the transistors 4071 and 4074are turned on, and the transistor 4072 is turned off. The secondterminal of the high-voltage P-type transistor 4051 of the first levelshifter 405 output the first indication signal LV_IN having a lowvoltage level (e.g., 0V). The second terminal of the high-voltage P-typetransistor 4061 of the second level shifter 406 outputs the secondindication signal LV_INB having a high voltage level (e.g., 5V). Assuch, the latch circuit 407 outputs the first square-wave signal LV_SNS0corresponding to a logic low level (e.g., 0V) and the second square-wavesignal LV_SNS0B corresponding to a logic high level (e.g., 5V). Thelogic gate 4131 continuously outputs the block signal SRBLK at a logiclow level (e.g., 0V). Accordingly, the latch control circuit 4134 mayoutput the low-voltage signal LV_OUT having a low voltage level (such as0V) according to the first square-wave signal LV_SNS0 and the secondsquare-wave signal LV_SNS0B not delayed by the first delay circuit 4132and the second delay circuit 4133 being leading edge-triggered.

At time t4, the second pulse generator 404 provides a sustain signalfollowing the pulse signal and having a low current level (e.g., 100 μA)of the second input signal PC2 to maintain the state of the transistors4071 to 4073 of the latch circuit 407, so that the latch circuit 407maintains outputting the second square-wave signal LV_SNS0Bcorresponding to a logic high level (e.g., 5V). As such, the circuitpower consumption can be effectively reduced, and the latch circuit 407can also be kept in a locked state.

In other words, the pulse signal and the sustain signal of the firstinput signal PC1 occur during a period of the high-voltage signal HV_INis at a high voltage level (e.g., 10V), and the first input signal PC1having a zero current level (e.g., 0 A) during a period of thehigh-voltage signal HV_IN is at a low voltage level (e.g., 5V). Thepulse signal and the sustain signal of the second input signal PC2 occurduring a period of the high-voltage signal HV_IN is at a low voltagelevel (e.g., 5V) (i.e., the period when the inverted high-voltage signalHV_INB is at a high voltage level (e.g., 10 V)), and the second inputsignal PC2 having a zero current level (e.g., OA) during a period of thehigh-voltage signal HV_IN is at a high voltage level (e.g., 10 V) (i.e.,the period when the inverted high-voltage signal HV_INB is at a lowvoltage level (e.g., 5V)). In addition, a duration of the pulse signalof the first input signal PC1 and the second input signal PC2 may be 10%to 20% of a time length of a duty cycle of the high-voltage signalHV_IN.

Between time t5 and time t6, since a high-voltage power HV_PWR and thehigh-voltage ground signal HV_GND rise, a current IC1, generated byparasitic capacitances 4052 and 4062 between the control terminals andthe second terminals of the high-voltage P-type transistors 4051 and4061 based on charge sharing, forms the first and second indicationsignals LV_IN and LV_INB at a high level to be provided to the latchcircuit 407, so that the latch circuit 407 outputs the first square-wavesignal LV_SNS0 corresponding to a logic high level (e.g., 5V) andcontinuously output the second square-wave signal LV_SNS0B correspondingto a logic high level (e.g., 5V). As such, the logic gate 4131 switchesto outputting the block signal SRBLK at a logic high level (e.g., 5V).Accordingly, the latch control circuit 4134 may lock the output of thelatch control circuit 4134 according to the block signal SRBLK tomaintain outputting the low-voltage signal LV_OUT at a low voltage level(e.g., 0V), without being affected by the currents IC1 and IC2.

At time t6, since the high-voltage power HV_PWR and the high-voltageground signal HV_GND stop rising, the respective parasitic capacitances4052 and 4062 of the high-voltage P-type transistors 4051 and 4061 stoptransmitting the currents IC1 and IC2, so that the on-resistance of thetransistor 4073 is lower than that of the transistor 4072. As such, thevoltage level of the first square-wave signal LV_SNS0 is pulled down bythe transistor 4073, and turns from a logic high level (e.g., 5V) to alogic low level (e.g., 0V). The logic gate 4131 switches to outputtingthe block signal SRBLK at a logic low level (e.g., 0V) to unlock theoutput of the latch control circuit 4134. The latch control circuit 4134outputs the low-voltage signal LV_OUT having a low voltage level (e.g.,0V) according to the first square-wave signal LV_SNS0 corresponding to alogic low level (e.g., 0V) and the second square-wave signal LV_SNS0Bcorresponding to a logic high level (e.g., 5V). In addition, the signalchanges and circuit operations from time t7 to time t9 are the same asthose described in the examples above of time t1 to time t3, and willthus not be repeatedly described here.

In summary of the foregoing, according to the embodiments of thedisclosure, the level shifter circuit may generate two input signalsincluding a pulse signal and a sustain signal through two pulsegenerators to reduce power consumption, and may generate twocorresponding indication signals for the determination circuit toaccordingly generate a correct and stable low-voltage signal. The levelshifter circuit of an embodiment of the disclosure is not likely to beaffected by changes in the high-voltage ground signal and thehigh-voltage power.

It will be apparent to those skilled in the art that variousmodifications and variations can be made to the disclosed embodimentswithout departing from the scope or spirit of the disclosure. In view ofthe foregoing, it is intended that the disclosure covers modificationsand variations provided that they fall within the scope of the followingclaims and their equivalents.

What is claimed is:
 1. A level shifter circuit of a driving device,configured to convert a high-voltage signal into a low-voltage signal,the level shifter circuit comprising: a first pulse generator providinga first input signal according to the high-voltage signal, wherein thefirst input signal comprises a pulse signal having a first current leveland a sustain signal following the pulse signal and having a secondcurrent level, and the first current level is higher than the secondcurrent level; a first level shifter coupled to the first pulsegenerator, and receiving the first input signal to generate a firstindication signal; a second pulse generator providing a second inputsignal according to the high-voltage signal, wherein the second inputsignal comprises the pulse signal and the sustain signal following thepulse signal; a second level shifter coupled to the second pulsegenerator, and receiving the second input signal to generate a secondindication signal; and a determination circuit coupled to the firstlevel shifter and the second level shifter, and generating thelow-voltage signal according to the first indication signal and thesecond indication signal, wherein the sustain signal of the first inputsignal is cut off according to a falling edge of the high-voltagesignal, and the sustain signal of the second input signal is cut offaccording to a rising edge of the high-voltage signal.
 2. The levelshifter circuit according to claim 1, wherein the pulse signal and thesustain signal of the first input signal occur during a periodcorresponding to when the high-voltage signal is at a high voltagelevel.
 3. The level shifter circuit according to claim 1, wherein thepulse signal and the sustain signal of the second input signal occurduring a period corresponding to when the high-voltage signal is at alow voltage level.
 4. The level shifter circuit according to claim 1,wherein the first current level is ten times or more higher than thesecond current level.
 5. The level shifter circuit according to claim 1,wherein a duration of the pulse signal of the first input signal and thesecond input signal is 10% to 20% of a time length of a duty cycle ofthe high-voltage signal.
 6. The level shifter circuit according to claim1, wherein the determination circuit comprises: a latch circuit coupledto the first level shifter and the second level shifter, and generatinga first square-wave signal and a second square-wave signal according tothe first indication signal and the second indication signal; and adetermination logic coupled to the latch circuit, and generating thelow-voltage output signal according to the first square-wave signal andthe second square-wave signal.
 7. The level shifter circuit according toclaim 6, further comprising a diode, wherein a first terminal of thediode is coupled to the latch circuit, and a second terminal of thediode is coupled to the second level shifter.
 8. The level shiftercircuit according to claim 6, wherein the determination logic comprises:a logic gate receiving the first square-wave signal and the secondsquare-wave signal, and accordingly generating a block signal; and alatch control circuit generating the low-voltage signal according to thefirst square-wave signal, the second square-wave signal, and the blocksignal.
 9. The level shifter circuit according to claim 6, wherein thedetermination logic further comprises: a first delay circuit and asecond delay circuit respectively receiving the first square-wave signaland the second square-wave signal and generating a delayed firstsquare-wave signal and a delayed second square-wave signal, wherein thedetermination logic generates the low-voltage signal according to thedelayed first square-wave signal and the delayed second square-wavesignal.
 10. The level shifter circuit according to claim 1, wherein thedriving device receives a pulse width modulation signal and generates adriving signal, and the driving device further comprises: a logic unitreceiving the pulse width modulation signal and generates a logic outputsignal; a driving signal level shifter circuit coupled to the logicunit, receiving the logic output signal, and converting the logic outputsignal from a low voltage domain into a high voltage domain; a firstdriver coupled to the driving signal level shifter circuit, andgenerating the driving signal according to the logic output signal inthe high voltage domain; and the level shifter circuit coupled betweenthe first driver and the logic unit, obtaining the high-voltage signalaccording to the driving signal, and converting the high-voltage signalinto the low-voltage signal.